Abstract
Two-dimensional (2D) transition metal dichalcogenides (TMDs), like MoS2, have unique electronic and optical properties, which can further be tuned using ion bombardment and post-synthesis ion-beam mediated methods combined with exposure of the irradiated sample to precursor gases. The optimization of these techniques requires a complete understanding of the response of 2D TMDs to ion irradiation, which is affected by the reduced dimensionality of the system. By combining analytical potential molecular dynamics with first-principles calculations, we study the production of defects in free-standing MoS2 sheets under noble gas ion irradiation for a wide range of ion energies when nuclear stopping dominates, and assess the probabilities for different defects to appear. We show that depending on the incident angle, ion type and energy, sulfur atoms can be sputtered away predominantly from the top or bottom layers, creating unique opportunities for engineering mixed MoSX compounds where X are chemical elements from group V or VII. We study the electronic structure of such systems, demonstrate that they can be metals, and finally discuss how metal/semiconductor/metal junctions, which exhibit negative differential resistance, can be designed using focused ion beams combined with the exposure of the system to fluorine.
Highlights
Beams of energetic ions and electrons are powerful tools to change the morphology and properties of both bulk [1, 2] and nano [3,4,5] materials
We study the electronic structure of such systems, demonstrate that they can be metals, and discuss how metal/semiconductor/metal junctions, which exhibit negative differential resistance, can be designed using focused ion beams combined with the exposure of the system to fluorine
For a wide range of ion energies, in the regime where nuclear stopping dominates, and various incident angles we showed that the most prolific defects which appear under ion bombardment are S vacancies
Summary
Beams of energetic ions and electrons are powerful tools to change the morphology and properties of both bulk [1, 2] and nano [3,4,5] materials. This is relevant to two-dimensional (2D) systems, as their ‘thickness’ is smaller than the ranges of even lowenergy particles, so that the whole structure can be treated, as opposed to macroscopically large objects where much higher energies of electrons and especially ions are required, and the effects of irradiation on sample morphology are spatially nonuniform. Examples of post-synthesis beammediated treatments of 2D materials include doping of hexagonal boron nitride with carbon [22], or graphene with metal atoms [23]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
